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1. How a highly acidic SH3 domain folds in the absence of its charged peptide target

   https://doi.org/10.1002/pro.4635  

   Jaramillo‐Martinez, Valeria; Dominguez, Matthew J.; Bell, Gemma M.; Souness, Megan E.; Carhart, Anna H.; Cuibus, M. Adriana; Masoumzadeh, Elahe; Lantz, Benjamin J.; Adkins, Aaron J.; Latham, Michael P.; et al (April 2023, Protein Science)

   Abstract Charged residues on the surface of proteins are critical for both protein stability and interactions. However, many proteins contain binding regions with a high net charge that may destabilize the protein but are useful for binding to oppositely charged targets. We hypothesized that these domains would be marginally stable, as electrostatic repulsion would compete with favorable hydrophobic collapse during folding. Furthermore, by increasing the salt concentration, we predict that these protein folds would be stabilized by mimicking some of the favorable electrostatic interactions that take place during target binding. We varied the salt and urea concentrations to probe the contributions of electrostatic and hydrophobic interactions for the folding of the yeast SH3 domain found in Abp1p. The SH3 domain was significantly stabilized with increased salt concentrations due to Debye–Huckel screening and a nonspecific territorial ion‐binding effect. Molecular dynamics and NMR show that sodium ions interact with all 15 acidic residues but do little to change backbone dynamics or overall structure. Folding kinetics experiments show that the addition of urea or salt primarily affects the folding rate, indicating that almost all the hydrophobic collapse and electrostatic repulsion occur in the transition state. After the transition state formation, modest yet favorable short‐range salt bridges are formed along with hydrogen bonds, as the native state fully folds. Thus, hydrophobic collapse offsets electrostatic repulsion to ensure this highly charged binding domain can still fold and be ready to bind to its charged peptide targets, a property that is likely evolutionarily conserved over 1 billion years. 

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2. Diversity in peptide recognition by the SH2 domain of SH2B1

   https://doi.org/10.1002/prot.25420  

   McKercher, Marissa A.; Guan, Xiaoyang; Tan, Zhongping; Wuttke, Deborah S. (December 2017, Proteins: Structure, Function, and Bioinformatics)

   Abstract SH2B1 is a multidomain protein that serves as a key adaptor to regulate numerous cellular events, such as insulin, leptin, and growth hormone signaling pathways. Many of these protein‐protein interactions are mediated by the SH2 domain of SH2B1, which recognizes ligands containing a phosphorylated tyrosine (pY), including peptides derived from janus kinase 2, insulin receptor, and insulin receptor substrate‐1 and −2. Specificity for the SH2 domain of SH2B1 is conferred in these ligands either by a hydrophobic or an acidic side chain at the +3 position C‐terminal to the pY. This specificity for chemically disparate species suggests that SH2B1 relies on distinct thermodynamic or structural mechanisms to bind to peptides. Using binding and structural strategies, we have identified unique thermodynamic signatures for each peptide binding mode, and several SH2B1 residues, including K575 and R578, that play distinct roles in peptide binding. The high‐resolution structure of the SH2 domain of SH2B1 further reveals conformationally plastic protein loops that may contribute to the ability of the protein to recognize dissimilar ligands. Together, numerous hydrophobic and electrostatic interactions, in addition to backbone conformational flexibility, permit the recognition of diverse peptides by SH2B1. An understanding of this expanded peptide recognition will allow for the identification of novel physiologically relevant SH2B1/peptide interactions, which can contribute to the design of obesity and diabetes pharmaceuticals to target the ligand‐binding interface of SH2B1 with high specificity. 

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3. MotifAnalyzer‐PDZ : A computational program to investigate the evolution of PDZ‐binding target specificity

   https://doi.org/10.1002/pro.3741  

   Valgardson, Jordan; Cosbey, Robin; Houser, Paul; Rupp, Milo; Van Bronkhorst, Raiden; Lee, Michael; Jagodzinski, Filip; Amacher, Jeanine F. (November 2019, Protein Science)

   Abstract Recognition of short linear motifs (SLiMs) or peptides by proteins is an important component of many cellular processes. However, due to limited and degenerate binding motifs, prediction of cellular targets is challenging. In addition, many of these interactions are transient and of relatively low affinity. Here, we focus on one of the largest families of SLiM‐binding domains in the human proteome, the PDZ domain. These domains bind the extreme C‐terminus of target proteins, and are involved in many signaling and trafficking pathways. To predict endogenous targets of PDZ domains, we developedMotifAnalyzer‐PDZ, a program that filters and compares all motif‐satisfying sequences in any publicly available proteome. This approach enables us to determine possible PDZ binding targets in humans and other organisms. Using this program, we predicted and biochemically tested novel human PDZ targets by looking for strong sequence conservation in evolution. We also identified three C‐terminal sequences in choanoflagellates that bind a choanoflagellate PDZ domain, theMonsiga brevicollisSHANK1 PDZ domain (mbSHANK1), with endogenously‐relevant affinities, despite a lack of conservation with the targets of a homologous human PDZ domain, SHANK1. All three are predicted to be signaling proteins, with strong sequence homology to cytosolic and receptor tyrosine kinases. Finally, we analyzed and compared the positional amino acid enrichments in PDZ motif‐satisfying sequences from over a dozen organisms. Overall,MotifAnalyzer‐PDZis a versatile program to investigate potential PDZ interactions. This proof‐of‐concept work is poised to enable similar types of analyses for other SLiM‐binding domains (e.g.,MotifAnalyzer‐Kinase).MotifAnalyzer‐PDZis available athttp://motifAnalyzerPDZ.cs.wwu.edu. 

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4. Membrane‐dependent assembly of Bruton's tyrosine kinase mediated by the Proline‐rich region and SH3 domain

   https://doi.org/10.1002/pro.70213  

   Fenton, Alexander D; Chung, Jean K (August 2025, Protein Science)

   Abstract Cellular membranes provide a unique platform for interactions that drive emergent behaviors in protein dynamics and cellular signaling, distinct from those observed in solution. We investigated the proline‐rich region (PRR) and Src Homology 3 (SH3) domains of Bruton's tyrosine kinase (Btk) and its phase separation driven by the weak interactions of regulatory domains at membrane surfaces. Using supported lipid bilayers (SLBs) and giant unilamellar vesicles (GUVs), we demonstrate that membrane localization amplifies weak PRR‐SH3 interactions, enabling the formation of higher‐order assemblies and phase‐separated condensates. These assemblies, previously undescribed by solution‐state studies, are supported by reductions in the lateral diffusion of membrane‐bound Btk molecules and the stabilization of reversible condensates at the membrane surface. Constructs containing the native PRR and SH3 domains reliably formed membrane‐associated clusters, while mutation or deletion of these domains lessened changes in diffusion and impaired condensate formation. Our findings establish the membrane as an essential mediator of PRR‐SH3‐driven phase separation in Btk, thereby advancing our understanding of membrane‐specific regulation in signaling protein dynamics. 

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5. Structural basis for the tryptophan sensitivity of TnaC-mediated ribosome stalling

   https://doi.org/10.1038/s41467-021-25663-8  

   van der Stel, Anne-Xander; Gordon, Emily R.; Sengupta, Arnab; Martínez, Allyson K.; Klepacki, Dorota; Perry, Thomas N.; Herrero del Valle, Alba; Vázquez-Laslop, Nora; Sachs, Matthew S.; Cruz-Vera, Luis R.; et al (December 2021, Nature Communications)

   null (Ed.)

   Abstract Free L-tryptophan (L-Trp) stalls ribosomes engaged in the synthesis of TnaC, a leader peptide controlling the expression of the Escherichia coli tryptophanase operon. Despite extensive characterization, the molecular mechanism underlying the recognition and response to L-Trp by the TnaC-ribosome complex remains unknown. Here, we use a combined biochemical and structural approach to characterize a TnaC variant (R23F) with greatly enhanced sensitivity for L-Trp. We show that the TnaC–ribosome complex captures a single L-Trp molecule to undergo termination arrest and that nascent TnaC prevents the catalytic GGQ loop of release factor 2 from adopting an active conformation at the peptidyl transferase center. Importantly, the L-Trp binding site is not altered by the R23F mutation, suggesting that the relative rates of L-Trp binding and peptidyl-tRNA cleavage determine the tryptophan sensitivity of each variant. Thus, our study reveals a strategy whereby a nascent peptide assists the ribosome in detecting a small metabolite. 

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